Nucleotide sequence of a ribosome attachment site of bacteriophage f2 RNA

Wanderings in biochemistry

My Ph.D. thesis in the laboratory of Severo Ochoa at New York University School of Medicine in 1962 included the determination of the nucleotide compositions of codons specifying amino acids. The experiments were based on the use of random copolyribonucleotides (synthesized by polynucleotide phosphorylase) as messenger RNA in a cell-free protein-synthesizing system. At Yale University, where I joined the faculty, my co-workers and I first studied the mechanisms of protein synthesis. Thereafter, we explored the interferons (IFNs), which were discovered as antiviral defense agents but were revealed to be components of a highly complex multifunctional system. We isolated pure IFNs and characterized IFN-activated genes, the proteins they encode, and their functions. We concentrated on a cluster of IFN-activated genes, the p200 cluster, which arose by repeated gene duplications and which encodes a large family of highly multifunctional proteins. For example, the murine protein p204 can be activated in numerous tissues by distinct transcription factors. It modulates cell proliferation and the differentiation of a variety of tissues by binding to many proteins. p204 also inhibits the activities of wild-type Ras proteins and Ras oncoproteins.

Identification of ribosome binding sites in Escherichia coli using neural network models

This study investigated the use of neural networks in the identification of Escherichia coli ribosome binding sites. The recognition of these sites based on primary sequence data is difficult due to the multiple determinants that define them. Additionally, secondary structure plays a significant role in the determination of the site and this information is difficult to include in the models. Efforts to solve this problem have so far yielded poor results. A new compilation of E. coli ribosome binding sites was generated for this study. Feedforward backpropagation networks were applied to their identification. Perceptrons were also applied, since they have been the previous best method since 1982. Evaluation of performance for all the neural networks and perceptrons was determined by ROC analysis. The neural network provided significant improvement in the recognition of these sites when compared with the previous best method, finding less than half the number of false positives when both models were adjusted to find an equal number of actual sites. The best neural network used an input window of 101 nucleotides and a single hidden layer of 9 units. Both the neural network and the perceptron trained on the new compilation performed better than the original perceptron published by Stormo et al. in 1982.

Translation of a synthetic two-cistron mRNA in Escherichia coli

A synthetic two-cistron expression system was constructed for the high-level expression of eukaryotic genes in Escherichia coli. This system was designed to overcome translational inhibition of mRNAs containing eukaryotic sequences. The first cistron in this system is a 31-base A + T-rich synthetic sequence that provides for efficient translation initiation. The second cistron contains the protein coding sequence for the eukaryotic gene. Insertion of the first cistron between the 5' untranslated region of the mRNA and the protein coding region separates the two and thereby potentially minimizes the formation of local secondary structures that might prevent ribosomes from binding and initiating translation. The 31-base cistron contains three nonsense codons (TAA), one in each of the three translational reading frames, and an 8-base Shine-Dalgarno sequence that is complementary to the 3' end of the 16S rRNA. The effects of translation of the first cistron in all three reading frames on the expression of the second cistron was examined. The most efficient expression of the second cistron seemed to occur when the stop codon that terminates translation of the first cistron is located 3' to the Shine-Dalgarno sequence and close to the AUG start codon for the second cistron. When the Shine-Dalgarno sequence was deleted from the first cistron, no detectable expression of the second cistron was observed. This two-cistron system has been used to express the gene encoding methionylalanyl bovine growth hormone with its native codons and the gene encoding methionyl human growth hormone at a level greater than 20% of total cell protein. In the case of human growth hormone, we show that the amount of gene product is not significantly diminished by placing a "functional" first cistron in front of a gene that can be expressed without a cistron.

Initiator tRNA may recognize more than the initiation codon in mRNA: a model for translational initiation

A special methionine tRNA (tRNAi) is universally required to initiate translation. Amongst species a tRNAi structural conservation is most apparent in the anticodon and T arms of the molecule but extends into the variable loop and the 3' strand of the D stem. This suggested that they could share a similar ancestral or current function in initiation of translation. We report that the sequence of bases neighboring the translational start codons of many eubacterial genes are complementary not only to the extended anticodon but also to the D and T loops of tRNAi. Study of the coding properties of tRNAi and of mutations that affect translation suggests that the translational start domain can be a mosaic of signals complementary to the loops of tRNAi. The hypothesis of multiple loop recognition suggests that unusual triplets can start prokaryotic and mitochondrial genes and predicts the occurrence of other reading frames. Furthermore, it suggests a unifying model for chain initiation based on RNA contacts and displacements.

Recognition of messenger RNA during translational initiation in Escherichia coli

The structural aspects of recognition by E. coli ribosomes of translational initiation regions on homologous messenger RNAs have been reviewed. Also discussed is the location of initiation region on mRNA, its confines, typical nucleotide sequences responsible for initiation signal, and the influence of RNA macrostructure on protein synthesis initiation. Most of the published DNA nucleotide sequences surrounding the start of various E. coli genes and those of its phages have been collected.

Increased synthesis in E. coli of fibroblast and leukocyte interferons through alterations in ribosome binding sites

Eleven chimeric plasmids have been constructed which direct the synthesis of mature human fibroblast (IFN-beta 1) or leukocyte interferon (IFN-alpha A) proteins under the control of the E. coli trp promoter. The plasmids differ with respect to the nucleotide spacing between the Shine-Dalgarno sequence of the trp leader and the ATG translation start signal of the interferon genes. By utilizing a unique Xba I endonuclease site located within the spacer region of the expression plasmids, the spacings were altered from 2-10 nucleotides or 7-15 nucleotides for the fibroblast and leukocyte interferon expression plasmids, respectively. The optimal spacing for expression, as determined by interferon assay, is 9 nucleotides for both types of transcripts, despite differences in nucleotide sequence within the spacer region and downstream from the AUG initiator. Yields of IFN-alpha A varied about six-fold, while among the different IFN-beta 1 expression plasmids a range of more than 100-fold in interferon production was observed. The difference in the range of variation between the IFN-alpha A and IFN-beta 1 plasmids is attributed partly to changes in messenger RNA secondary structure within the ribosome binding sites which affect message half-life.

Localization of A protein in the RNA-A protein complex of RNA phage MS2

The site of interaction of phage MS2 A protein on MS2 RNA was determined by analysing the base sequence of the RNA fragment which was released from the RNAase-resistant complex prepared by RNAase digestion of RNA-A protein complex. The result showed that there were two types of RNA fragment: one had a sequence which corresponded to the sequence of the 5'-side maturation region of MS2 RNA and the other corresponded to the sequence of the 3'-side untranslated region. These results were confirmed by a competition experiment in in vitro reconstitution system using f2 defective RNA, lacking about 30% of the 5'-side, and MS2 5FUra (5-fluorouracil) RNA, lacking about 35% of the 3'-side, as competitors. These results seem to indicate that the A protein is bound to at least two sites on MS2 RNA.

The ribosome binding sites recognized by E. coli ribosomes have regions with signal character in both the leader and protein coding segments

Oligonucleotide analysis, by a novel computerized procedure, was first applied to determine the sequence of an ideal E. coli promoter (Scherer et al., Nucl. Acids Res. 1978, 5:3759-3773) and has now been used to obtain the sequence of nucleotides that should be present in a messenger RNA for optimum binding to the E. coli ribosome. This sequence is: UU.UUAAAAAUUAAGGAGGUAUAUUAUGAAAAAAAUUAAAAAACUCAA AA U A AUA A CUC G. Comparison of this sequence with each of the 68 ribosome binding site sequences used to generate it shows a preference rather than an absolute requirement for a specific base in any given position. The preference for certain bases persists along the whole length of the RNA within the ribosome binding domain even though nearly half of that length includes translated codons. Thus messages without leader sequences (like lambda CI mRNA) can still have some affinity for the ribosome. Part of the model sequence is complementary to the 3'end of 16S rRNA.

Early gene expression in bacteriophage T7. I. In vivo synthesis, inactivation, and translational utilization of early mRNA's

In vivo decay rates for the individual T7 early mRNA species were determined. The physical half-lives, measured at 37 C, range from 1.1 min for gene 0.7 RNA to 4.5 min for gene 0.3 RNA. Physical half-lives, as observed after rifampin inhibition of RNA synthesis and polyacylamide electrophoresis of RNAs, are approximately 30% longer than functional half-lives, as observed by 14C-labeled amino acid uptake into individual T7 early proteins. The different RNA species are synthesized at grossly different rates, 0.3 RNA at four times the rate of 1.0 RNA, 0.7 RNA at twice the rate, and 1.1 and 1.3 RNAs at about the same or a slightly lower rate than 1.0 RNA. Rho-factor-mediated termination of transcription behind genes 0.3, 0.7, and perhaps behind 1.0 is inferred from these data. The in vivo translational utilization of the individual T7 early-message species was found to vary by not more than a factor of 2.

How ribosomes select initiator regions in mRNA: base pair formation between the 3' terminus of 16S rRNA and the mRNA during initiation of protein synthesis in Escherichia coli

Initiation complexes formed by E. coli ribosomes in the presence of 32P-labeled A protein initiator region from R17 bacteriophage Rna have been treated with colicin E3 and disassembled by exposure to 1% sodium dodecyl sulfate. Electrophoresis on 9% polyacrylamide gels reveals a dissociable complex containing the 30-nucleotide-long messenger fragment and the 50-nucleotide-long colicin fragment, which arises from the 3' terminus of the 16S RNA. The complex is a pure RNA-RNA hybird; it is apparently maintained by a seven-base complementarity between the two RNA fragments. Detection of this mRNA-rRNA complex strongly supports the hypothesis that during the initiation step of protein biosynthesis the 3' end of 16S RNA base pairs with the polypurine stretch common to initiator regions in E. coli and bacteriophage mRNAs. The implications of our findings with respect to the molecular mechanism of initiation site selection and mRNA binding to ribosomes, the role of rRNA in ribosome function, and species specificity in translation are explored.

Nucleotide sequence of a viral RNA fragment that binds to eukaryotic ribosomes

The nucleotide sequence has been determined for the first 53 bases of brome mosaic virus RNA4, the monocistronic messenger for brome mosaic virus coat protein. The sequence includes the binding site for wheat embryo ribosomes. The 5'-terminal base is a modified guanosine attached to the penultimate base through a 5' p-p-p 5' link. The initiating AUG codon is only 10 nucleotides from the 5'-terminus. The triplets following the AUG codon correspond to the known sequence of brome mosaic virus coat protein.

Determinant of cistron specificity in bacterial ribosomes

The sequence of the 3'-terminus of 16S RNA from different bacteria has been determined. Complementarity relationships between this sequence and a purine-rich tract in the ribosome binding site of different bacterial mRNAs suggest that the 3'-end of 16S RNA determines the intrinsic capacity of ribosomes to translate a particular cistron.

A possible role of the 5' terminal sequence of 16S ribosomal RNA in the recognition of initiation sequences for protein synthesis

Extensive complementarity is found between the 5' end of 16S ribosomal RNA and protein synthesis initiation sites of bacteriophage RNA. Hybrids can be constructed from base sequences of 16S-RNA and two initiation regions on phage RNA. A model is proposed for the involvement of 16S-RNA in the unfolding of hairpin loops containing the initiation codon AUG.

The 3'-terminal sequence of Escherichia coli 16S ribosomal RNA: complementarity to nonsense triplets and ribosome binding sites

With a stepwise degradation and terminal labeling procedure the 3'-terminal sequence of E. coli 16S ribosomal RNA is shown to be Pyd-A-C-C-U-C-C-U-U-A(OH). It is suggested that this region of the RNA is able to interact with mRNA and that the 3'-terminal U-U-A(OH) is involved in the termination of protein synthesis through base-pairing with terminator codons. The sequence A-C-C-U-C-C could recognize a conserved sequence found in the ribosome binding sites of various coliphage mRNAs; it may thus be involved in the formation of the mRNA.30S subunit complex.

Reinitiation of a lac repressor fragment at a codon other than AUG

52 Spontaneous nonsense mutants in the lac i gene of Escherichia coli were isolated and characterized. All mutants located early in the gene show negative complementation in vivo with a wild-type i gene in a recA diploid strain. In vitro studies show that those mutants that display negative complementing activity in vivo also make lac repressor fragments retaining inducer binding and immunological crossreactivity with wild-type repressor. Amino-acid sequence analysis of these fragments shows that they arise by reinitiation at internal sities of the i message after chain termination at a prior amber or ochre codon. There are at least two different internal reinitiation sites in the first 200 nucleotides of the translated part of the i message. The first site corresponds to the first internal in phase AUG codon, which specifies the methionine residue at position 42 of the repressor protein. This site can be activated by an amber codon, 45 nucleotides before the AUG codon. The second site is only 60 nucleotides past the first site and can be activated by an amber mutation derived from residue 60 of the protein. The second initiation codon specifies the amino-acid leucine in the wild-type repressor, but the reinitiated fragment shows an amino-terminal methionine residue at this position. Therefore, the second initiation site seems to involve an in vivo ambiguity of the genetic code in that the same codon can be translated into two different amino acids depending on the recognition of this codon during initiation (when methionine is inserted) or elongation of protein synthesis (when leucine is inserted). The possibility that a codon other than AUG can act as an initiation codon in vivo is discussed.

Discriminatory ribosome rebinding of isolated regions of protein synthesis initiation from the ribonucleic acid of bacteriophage R17

To determine whether bacterial ribosomes recognize a distinguishing feature in the immediate vicinity of actual initiator codons or are directed to these sites through involvement of other portion(s) of the mRNA molecule, the interaction between ribosomes and defined (32)P-labeled initiator fragments from R17 RNA was studied. When incubated with mixtures of the three sites, ribosomes from Bacillus stearothermophilus (which initiate only the A protein on intact phage RNA) are able to select out the A fragment and discriminate against the coat and replicase initiator regions. By contrast, Escherichia coli ribosomes do not rebind that coat-protein region of R17 most efficiently, as they in the native RNA, but likewise prefer the A-protein initiator fragment. In both cases, ribosome binding of the isolated A site is comparable by several criteria to normal polypeptide-chain initiation on an intact R17 messenger RNA in vitro. E. coli ribosomal preference for the A site is confirmed in experiments with randomly fragmented R17 RNA, by both the initiation dipeptide and ribosome protection assay. Thus the A-protein ribosome-binding site of R17 RNA appears intrinsically to be a good initiator, while efficient recognition of the coat and replicase regions requires the participation of some portion of the remainder of the phage RNA molecule.

Nucleotide sequences of similar size from the coliphage R17 genome

A sequence of 33 nucleotides from the coliphage R17 RNA genome was determined. It constitutes the main component of a mixture of fragments that migrate together on electrophoresis in a separation according to molecular weight. Fragments of comparable chain length from 3' end of RNA from coliphage R17, from a region preceding and overlapping the coat-protein cistron ribosome binding site and from the beginning of the A-protein cistron, were also found and characterized. ;Hairpin'-like secondary structures are proposed for the longer fragments, one of which appears to have a tetranucleotide excised in the loop region.

A sequence of seventy-three nucleotides from the coliphage R17 genome

1. A sequence of 73 nucleotides of the RNA genome from coliphage R17 was determined. It can be read through in only one translational frame. The fragment is not part of the coatprotein cistron (Min Jou et al., 1972), nor does it come from the untranslated sequences described previously (Steitz, 1969; Nichols, 1970; Cory et al., 1970; de Wachter et al., 1971; Contreras et al., 1971; Cory et al., 1972). It contains two sequences of 23 and 24 nucleotides, 22 of which are identical. This kind of reiteration is the first one found in bacteriophage nucleic acid. 2. Improved conditions were found and tested for blocking oligonucleotides with carbodi-imide and cleaving by ribonuclease A at cytidylate residues. 3. A synthetic medium is described which allows labelling in vivo with (32)P to give specific radioactivities higher than those obtained in the procedures used previously.